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Shi Junqiang, Yin Xunqiang, Qiao Fangli. Optimizing the spatial ocean observation system based on data assimilation assessment: the Gulf of Thailand as an example[J]. Haiyang Xuebao, 2018, 40(2): 14-29. doi: 10.3969/j.issn.0253-4193.2018.02.002
Citation: Shi Junqiang, Yin Xunqiang, Qiao Fangli. Optimizing the spatial ocean observation system based on data assimilation assessment: the Gulf of Thailand as an example[J]. Haiyang Xuebao, 2018, 40(2): 14-29. doi: 10.3969/j.issn.0253-4193.2018.02.002

Optimizing the spatial ocean observation system based on data assimilation assessment: the Gulf of Thailand as an example

doi: 10.3969/j.issn.0253-4193.2018.02.002
  • Received Date: 2017-02-13
  • The cost for ocean observation system is very high, and the scientific design of observation system can make it effective. Taking the high frequency radar system of the Gulf of Thailand as an example, we established a three-dimensional ocean circulation model using FVCOM. A series of evaluation numerical experiments were carried out to assess the performance of the existing observational radar system. The simulated surface current data in three observation regions were assimilated by means of various combinations using an efficient ensemble Kalman filter data assimilation method. The experimental results showed that the coastal surface current observation system plays a quite positive role in improving the current simulation in the whole domain, although the observation only covers small parts of this area. The existing observation system is helpful for ocean circulation simulation and forecast. However, the improvement effect for three observation regions was quite different, which means the current observation system is not effective and need to be optimized. In addition, this study used the ensemble transform Kalman filter optimal observation scheme to explore the ideal deployment of observational stations, which could be a useful guidance for future re-design of this observation system.
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  • Ballabrera-Poy J, Hackert E, Murtugudde R, et al. An observing system simulation experiment for an optimal moored instrument array in the tropical Indian ocean[J]. Journal of Climate, 2007, 20(13):3284-3299.
    She Jun, Hoyer J L, Larsen J. Assessment of sea surface temperature observational networks in the Baltic Sea and North Sea[J]. Journal of Marine Systems, 2007, 65(1/4):314-335.
    Fu W, Høyer J L, She J. Assessment of the 3-D temperature and salinity observational networks in the Baltic Sea and North Sea[J]. Ocean Science Discussions, 2010, 7(5):1627-1668.
    Sakov P, Oke P R. Objective array design:application to the tropical indian ocean[J]. Journal of Atmospheric and Oceanic Technology, 2008, 25(5):794-807.
    叶冬, 王瑞文. 基于集合同化方法的南海北部最优观测实验[J]. 海洋通报, 2011, 30(3):252-257. Ye Dong, Wang Ruiwen. Optimal observation experiment in the northern South China Sea based on the ensemble assimilation method[J]. Marine Science Bulletin, 2011, 30(3):252-257.
    王瑞文, 叶冬. 中国近海现场海洋观测系统设计评估[J]. 海洋通报, 2012, 31(2):121-130. Wang Ruiwen, Ye Dong. Assessment on the design of in-situ ocean observing system in Chinese marginal seas[J]. Marine Science Bulletin, 2012, 31(2):121-130.
    Panteleev G, Yaremchuk M, Francis O, et al. Configuring high frequency radar observations in the Southern Chukchi Sea[J]. Polar Science, 2013, 7(7):72-81.
    Panteleev G, Yaremchuk M, Stroh J, et al. Optimization of the High-Frequency Radar Sites in the Bering Strait Region[J]. Journal of Atmospheric and Oceanic Technology, 2015, 32(2):297-309.
    Chen C S, Beardsley R C, Cowles G. An unstructured grid, finite-volume coastal ocean model:FVCOM User Manual, Second edition[J]. Oceanography, 2006, 19(1):78-89.
    Weatherall P, Marks K M, Jakobsson M, et al. A new digital bathymetric model of the world's oceans[J]. Earth and Space Science, 2016, 2(8):331-345.
    Yin Xunqiang, Qiao Fangli, Shu Qi. Using ensemble adjustment Kalman filter to assimilate Argo profiles in a global OGCM[J]. Ocean Dynamics, 2011, 61(7):1017-1031.
    Pawlowicz R, Beardsley B, Lentz S. Classical tidal harmonic analysis including error estimates in MATLAB using T_TIDE[J]. Computers & Geosciences, 2002, 28(8):929-937.
    Atlas R, Hoffman R N, Ardizzone J, et al. Development of a new cross-calibrated multiplatform (CCMP) ocean surface wind product[C]//Paper presented at AMS 13th Conference on Integrated Observing and Assimilation Systems for Atmosphere, Oceans, and Land Surface (IOAS-AOLS). Phoenix, AZ:AMS, 2009.
    Scott J, Wentz F J, Hoffman R N, et al. Improvements and advances to the cross-calibrated multi-platform (CCMP) ocean vector wind analysis (V2.0 release)[C]//AGU Ocean Sciences Meeting. Washington DC:AGU, 2016.
    Saha S, Moorthi S, Wu X, et al. The NCEP Climate Forecast System Version 2[J]. Journal of Climate, 2014, 27(6):2185-2208.
    Kara A B, Barron C N, Wallcraft A J, et al. Advantages of fine resolution SSTs for small ocean basins:Evaluation in the Black Sea[J]. Journal of Geophysical Research:Atmospheres, 2008, 113(C8):C08013.
    Chen Xue'en, Zhan Peng, Chen Jinrui, et al. Numerical study of current fields near the Changjiang Estuary and impact of Quick-EnKF assimilation[J]. Acta Oceanologica Sinica, 2011, 30:33.
    Zhao Jian, Chen Xue'en, Xu Jianling, et al. Assimilation of surface currents into a regional model over Qingdao coastal waters of China[J]. Acta Oceanologica Sinica, 2013, 32(7):21-28.
    Parrish D F, Derber J C. The National Meteorological Center's spectral statistical-interpolation analysis system[J]. Monthly Weather Review, 1992, 120(8):1747-1763.
    Rabier F, Mcnally A, Andersson E, et al. The ECMWF implementation of three-dimensional variational assimilation (3D-Var). Ⅱ:Structure functions[J]. Quarterly Journal of the Royal Meteorological Society, 1998, 124(550):1809-1829.
    Stansfield K, Garrett C. Implications of the salt and heat budgets of the Gulf of Thailand[J]. Journal of Marine Research, 1997, 55(5):935-963.
    刘科峰, 蒋国荣, 陈奕德, 等. 基于卫星漂流浮标的南海表层海流观测分析[J]. 热带海洋学报, 2014, 33(5):13-21. Liu Kefeng, Jiang Guorong, Chen Yide, et al. Analysis of upper-ocean surface currents of the South China Sea derived from satellite-tracked drifter data[J]. Journal of Tropical Oceanography, 2014, 33(5):13-21.
    Buranapratheprat A, Luadnakrob P, Yanagi T, et al. The modification of water column conditions in the Gulf of Thailand by the influences of the South China Sea and monsoonal winds[J]. Continental Shelf Research, 2016, 118:100-110.
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